Cooperative interactions among protein and RNA components of the 50S ribosomal subunit of Escherichia coli.

Copperative interactions among constituents of the 50S ribosomal subunit of Escherichia coli have been analyzed in order to elucidate its assembly and structural organization. Proteins L5 and L18 were shown to be necessary and sufficient to effect the association of the 5S and 23S RNAs into a quaternary complex that contains equimolar amounts of all four components. Measurement of diffusion constants by laser light scattering revealed that integration of the 5S RNA induced the 23S RNA to adopt a somewhat more open conformation. An investigation of relationships among proteins associated with the central and 3' portions of the 23S RNA demonstrated that attachment of L5, L10 + L11, and L28 depends upon the RNA-binding proteins L16, L2, and L1 + L3 + L6, respectively, and that L2 interacts with the central segment of the 23S RNA. These data, as well as the results of others, have been used to construct a scheme that depicts both direct and indirect associations of the 5S RNA, the 23S RNA, and over two-thirds of the subunit proteins. The 5' third of the 23S RNA apparently organizes the proteins required to nucleate essential reactions, whereas a region within 500 to 1500 bases of its 3' terminus is associated primarily with proteins involved in the major functional activities of the 50S ribosomal particle.     

Complete mitochondrial DNA sequence of the important honey bee pest,Varroa destructor (Acari: Varroidae)

Mites in the genus Varroa are the primary parasites of honey bees on several continents. Genetic analyses based on Varroa mitochondrial DNA have played a central role in establishing Varroa taxonomy and dispersal. Here we present the complete mitochondrial sequence of the important honey bee pest Varroa destructor. This species has a relatively compact mitochondrial genome (15,218 bp). The order of genes encoding proteins is identical to that of most arthropods. Ten of 22 transfer RNAs are in different locations relative to hard ticks, and the 12S ribosomal RNA subunit is inverted and separated from the 16S rRNA by a novel non-coding region, a trait not yet seen in other arthropods. We describe a dispersed set of 45 oligonucleotide primers that can be used to address genetic questions in Varroa. A subset of these primers should be useful for taxonomic and phylogenetic studies in other mites and ticks. This revised version was published online in July 2006 with corrections to the Cover Date.     

Conformation of free and ribosome bound rRNAs from E.coli

The effect of protein moiety on the conformation of 16S and 23S RNA of the $\text{E.}\text{coli}$ ribosome has been studied by circular dichroic spectroscopy. Both rRNAs possess a comparable net content of ordered secondary structure which remains unchanged after association with ribosomal proteins into “core” particles or into complete 30S and 50S subunits, respectively. However, differences found in the stability and the cooperativity of melting of free and protein-associated rRNAs imply protein-caused variations in the distribution of the intramolecular hairpin stems and loops and/or changes in long range tertiary interactions which appear to be different for both rRNAs. While 23S RNA is maximally stabilized on the large subunit by the full set of proteins, 16S RNA on the complete small subunit shows lower stability but higher cooperativity in melting.     

Ribosomal proteins: XLIII. In vivo assembly of Escherichia coli ribosomal proteins

Isolation of ribosomal precursors from Escherichia coli K12 is described. The RNA and protein content of the precursor particles was determined.One physiologically stable precursor was found for the 30 S subunit. The assembly scheme is as follows: p16 S RNA + 9 proteins → p30 S (“21 S” precursor) p30 S + 12 proteins → 30 S subunit where p is precursor.Each of the two precursors for the 50 S subunit, P₁50 S and p₂50 S (“32 S” and “43 S” precursors, respectively), contains p5 S + p23 S RNA's in a 1:1 molar ratio. The assembly scheme is as follows: p23 S RNA + p5 S RNA + 16 or 17 proteins → p₁50 S

In contrast to the p₂50 S precursor the p₁50 S precursor is not similar to any core particles, which were obtained by treating 50 S subunits with different concentrations of LiCl or CsCl.The precursors p30 S and p₂50 S can be converted into active 30 S and 50 S sub-units, respectively, by incubation at 42 °C in the presence of ribosomal proteins and under RNA methylating conditions.     

Protection of specific sites in 23 S and 5 S RNA from chemical modification by association of 30 S and 50 S ribosomes.

The effect of 30S subunit attachment on the accessibility of specific sites in 5 S and 23 S RNA in 50 S ribosomal subunits was studied by means of the guanine-specific reagent kethoxal. Oligonucleotides surrounding the sites of kethoxal substitution were resolved and quantitated by diagonal electrophoresis. In contrast to the extensive protection of sites in 16 S RNA in 70 S ribosomes (Chapman &; Noller, 1977), only two strongly (approx. 90%) protected sites were detected in 23 S RNA. The nucleotide sequences at these sites are

in which the indicated kethoxal-reactive guanines (with K above them) are strongly protected by association of 30 S and 50 S subunits. The latter sequence has the potential to base-pair with nucleotides 816 to 821 of the 16 S RNA, a site which has been shown to be protected from kethoxal by 50 S subunits and essential for subunit association. Six additional sites in 23 S RNA are partially (30 to 50%) protected by 30 S subunits. One of these sequences,

is complementary to nucleotides 787 to 792 of 16 S RNA. a site which is also 50 S-protected and essential for association. Of the two kethoxal-reactive 5 S RNA sites in 50 S subunits, G₁₃ is partially protected in 70 S ribosomes. while G₄₁ remains unaffected by subunit association.The relatively small number of kethoxal-reactive sites in 23 S RNA that is strongly protected in 70 S ribosomes suggests that subunit association may involve contacts between single-stranded sites in 16 S RNA and 50 S subunit proteins or non-Watson-Crick interactions with 23 S RNA. in addition to the two suggested base-paired contacts.     

RNA-protein interactions in the ribosome: VIII. Co-operative interactions in the 50 S subunit of Escherichia coli

Six 50 S ribosomal subunit proteins, each unable to interact independently with the 23 S RNA, were shown to associate specifically with ribonucleoprotein complexes consisting of intact 23 S RNA, or fragments derived from it, and one or more RNA-binding proteins. In particular, L21 and L22 depend for attachment upon L20 and L24, respectively; L5, L10 and L11 interact individually with complexes containing L2 and L16; and one or both proteins of the $\text{L}\text{17}\text{L}\text{27}$ mixture are stimulated to bind in the presence of L1, L3, L6, L13 and L23. Moreover, L14 alone was found to interact with a fragment from the 3′ end of the 23 S RNA, even though it cannot bind to 23 S RNA. By correlating the data reported here with the findings of others, it has been possible to formulate a partial in vitro assembly map of the Escherichia coli 50 S subunit encompassing both the 5 S and 23 S RNAs as well as 21 of the 34 subunit proteins.     

Ribosome-DnaK interactions in relation to protein folding

Bacterial ribosomes or their 50S subunit can refold many unfolded proteins. The folding activity resides in domain V of 23S RNA of the 50S subunit. Here we show that ribosomes can also refold a denatured chaperone, DnaK, in vitro, and the activity may apply in the folding of nascent DnaK polypeptides in vivo. The chaperone was unusual as the native protein associated with the 50S subunit stably with a 1:1 stoichiometry in vitro. The binding site of the native protein appears to be different from the domain V of 23S RNA, the region with which denatured proteins interact. The DnaK binding influenced the protein folding activity of domain V modestly. Conversely, denatured protein binding to domain V led to dissociation of the native chaperone from the 50S subunit. DnaK thus appears to depend on ribosomes for its own folding, and upon folding, can rebind to ribosome to modulate its general protein folding activity.     

Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. II. Biochemistry.

1. Several nuclear mutants have been isolated which showed thermo- or cryo-sensitive growth on non-fermentable media. Although the original strain carried mitochondrial drug resistance mutations (CR, ER, OR and PR), the resistance to one or several drugs was suppressed in these mutants. Two of them showed a much reduced amount of the mitochondrial small ribosomal subunit (37S) and of the corresponding 16S ribosomal RNA. Two dimensional electrophoretic analysis did not reveal any change in the position of any of the mitochondrial ribosomal proteins. However one of the mitochondrial ribosomal proteins. However one of the mutants showed a striking decrease in the amounts of three ribosomal proteins S3, S4 and S15. 2. Four temperature-sensitive mitochondrial mutations have been localized in the region of the gene coding for the large mitochondrial ribosomal RNA (23S). These mutants all showed a marked anomaly in the mitochondrial large ribosomal subunit (50S) and/or the corresponding 23S ribosomal RNA.     

Structural changes of ribosome by the action of ethylene glycol.

The denaturation of ribosome and RNA by ethylene glycol (EG) has been studied in an attempt to further understand the conformation and stability of the ribosome. At high concentrations of EG, the ribosome, its subunits, and 16S RNA undergo drastic structural changes as shown by circular dichroism, ultraviolet absorption spectroscopy, and sedimentation velocity. Two separate conformational transitions were observed for the 30S subunit; one from 30 to 50% EG and another from 60 to 90% EG. This observation suggests the presence of two "domains" in the 30S subunit which differ in their stability. However, the 50S subunit undergoes a single sharp transition at 60 to 90% EG, consistent with the notion of a highly cooperative conformation. Association of the subunits stablizes part of the 30S subunit since the transition curve for the 70S ribosome does not exhibit significant change at the low EG concentration region as seen for the 30S subunit. Removal of proteins from the 30S subunit broadens the transition curve to lower EG concentrations and suggests the role of proteins in stabilizing the conformation of the 16S RNA.     

The use of 2-iminothiolane as an RNA-protein cross-linking agent in Escherichia coli ribosomes, and the localisation on 23S RNA of sites cross-linked to proteins L4, L6, L21, L23, L27 and L29.

When E. coli ribosomal subunits are reacted with 2-iminothiolane and then subjected to a mild ultraviolet irradiation, an RNA-protein cross-linking reaction occurs. About 5% of the total protein in each subunit becomes cross-linked to the RNA, and a specific sub-set of proteins is involved in the reaction. In the case of the 50S subunit, the sites of cross-linking to the 23S RNA have been determined for six of these proteins: protein L4 is cross-linked within an oligonucleotide comprising positions 613-617 in the 23S sequence, L6 within positions 2473-2481, L21 within positions 540-548, L23 within positions 137-141, L27 within positions 2332-2337 and L29 within positions 99-107.     

Letter: Binding of 50 S ribosomal subunit proteins to 23 S RNA of Escherichia coli

Each of the 50 S ribosomal subunit proteins of Escherichia coli was tested independently in two laboratories for its ability to bind specifically to 23 S RNA. Four new RNA-binding proteins, L1, L3, L4 and L13 were identified in this way. Consistent with earlier work, proteins L2, L6, L16, L20, L23 and L24 were found to interact directly and independently with 23 S RNA as well. No binding of L17 was detected, however, contrary to previous reports, and the results for L19 were variable. The molar ratio of protein and RNA in each complex was measured at saturation. Significant differences in binding stoichiometry were noted among the various proteins. In addition, saturation levels were found to be influenced by the state of both the RNA and the proteins.     

Binding of Escherichia coli ribosomal proteins to 23S RNA under reconstitution conditions for the 50S subunit.

The RNA binding capacity of 50S proteins from E. coli ribosomes has been tested under improved conditions; purified proteins active in reconstitution assays were used, and the binding was studied under the conditions of the total reconstitution procedure for the 50S subunit. The results are: 1) Interaction of 23S RNA was found with 17 proteins, namely L1, L2, L3, L4, L7/L12, L9, L10, L11, L15, L16, L17, L18, L20, L22, L23, L24 and L29. 2) The proteins L1, L2, L3, L4, L9, L23 and L24 bound to 23S RNA at a level of about one copy per RNA molecule, whereas L20 could bind more than one copy (no saturation was observed at 1.8 copies per 23S RNA), and the other proteins bound 0.2--0.6 copies per RNA. 3) L1, L3, L7/L12 showed a slight binding to 16S RNA, L26 (identical with S20) strong binding to 16S RNA. 4) The binding of L2, L7/L12, L10, L11, L15, L16 and L18 was preparation sensitive, i.e. the binding ability changed notably from preparation to preparation. 5) All proteins bound equally well to 23S RNA in presence of 4 and 20 mM Mg2+, respectively, except L2, L3, L4, L7/L12, L9, L10, L15, L16 and L18, which bound less strongly at 20 mM than at 4 mM Mg2+.     

Interaction of tetracycline with RNA: photoincorporation into ribosomal RNA of Escherichia coli.

Photolysis of [3H]tetracycline in the presence of Escherichia coli ribosomes results in an approximately 1:1 ratio of labelling ribosomal proteins and RNAs. In this work we characterize crosslinks to both 16S and 23S RNAs. Previously, the main target of photoincorporation of [3H]tetracycline into ribosomal proteins was shown to be S7, which is also part of the one strong binding site of tetracycline on the 30S subunit. The crosslinks on 23S RNA map exclusively to the central loop of domain V (G2505, G2576 and G2608) which is part of the peptidyl transferase region. However, experiments performed with chimeric ribosomal subunits demonstrate that peptidyltransferase activity is not affected by tetracycline crosslinked solely to the 50S subunits. Three different positions are labelled on the 16S RNA, G693, G1300 and G1338. The positions of these crosslinked nucleotides correlate well with footprints on the 16S RNA produced either by tRNA or the protein S7. This suggests that the nucleotides are labelled by tetracycline bound to the strong binding site on the 30S subunit. In addition, our results demonstrate that the well known inhibition of tRNA binding to the A-site is solely due to tetracycline crosslinked to 30S subunits and furthermore suggest that interactions of the antibiotic with 16S RNA might be involved in its mode of action.     

Covalent cross-linking of ribosomal RNA and proteins by methylene blue-sensitized photooxidation.

Ribosomal proteins are covalently cross-linked to ribosomal RNA by irradiation with visible light in the presence of methylene blue and O2. Proteins S3, S4, S5 and S7 from the 30 S subunit of Escherichia coli ribosomes and L2 and L3 from the 50 S subunit are among the cross-linked proteins. S3 and S5 had not previously been identified as RNA-binding proteins.     

Secondary structure of total protein and 23S RNA in 50S ribosomal subunits and in the isolated state

Optical and sedimentational studies of isolated 23S RNA, total proteins and some RNP-complexes of the 50S subunits were carried out. It is shown that the secondary structure content of 23S RNA in the ribosome is lower than in the isolated state. Ribosomal proteins stabilize the 23S RNA structure and make it more compact. At the same time they cause some unwinding effect on the secondary structure of the 23S RNA and possibly fix some segments of the 23S RNA in the conformation necessary for its function. In turn, the 23S RNA increased somewhat the level of the total ordered secondary structure in the ribosomal proteins. There was no considerable change of the ratio between the alpha- and beta-structures in the proteins.     

Characterization of DbpA, an Escherichia coli DEAD box protein with ATP independent RNA unwinding activity.

DbpA is a putative Escherichia coli ATP dependent RNA helicase belonging to the family of DEAD box proteins. It hydrolyzes ATP in the presence of 23S ribosomal RNA and 93 bases in the peptidyl transferase center of 23S rRNA are sufficient to trigger 100% of the ATPase activity of DbpA. In the present study we characterized the ATPase and RNA unwinding activities of DbpA in more detail. We report that-in contrast to eIF-4A, the prototype of the DEAD box protein family-the ATPase and the helicase activities of DbpA are not coupled. Moreover, the RNA unwinding activity of DbpA is not specific for 23S rRNA, since DbpA is also able to unwind 16S rRNA hybrids. Furthermore, we determined that the ATPase activity of DbpA is triggered to a significant extent not only by the 93 bases of the 23S rRNA previously reported but also by other regions of the 23S rRNA molecule. Since all these regions of 23S rRNA are either part of the 'functional core' of the 50S ribosomal subunit or involved in the 50S assembly, DbpA may play an important role in the ribosomal assembly process.     

Analysis of cytoplasmic RNA and polyribosmomes from feline leukemia virus-infected cells.

Cytoplasmic virus-specific RNA and polyribosomes from a chronically infected feline thymus tumor cell line, F-422, were analyzed by using in vitro-synthesized feline leukemia virus (Rickard strain) (R-FeLV) complementary DNA (cDNA) probe. By hybridization kinetics analysis, cytoplasmic, polyribosomat, and nuclear RNAs were found to be 2.1, 2.6, and 0.7% virus specific, respectively. Size classes within subcellular fractions were determined by sucrose gradient centrifugation in the presence of dimethyl sulfoxide followed by hybridization. The cytoplasmic fraction contained a 28S size class, which corresponds to the size of virion subunit RNA, and 36S, 23S, and 15 to 18S RNA species. The virus-specific 36S, 23S, and 15 to 18S species but not the 28S RNA were present in both the total and polyadenylic acid-containing polyribosomal RNA. Anti-FeLV gamma globulin bound to rapidly sedimenting polyribosomes, with the peak binding at 400S. The specificity of the binding for nascent virus-specific protein was determined in control experiments that involved mixing polyribosomes with soluble virion proteins, absorption of specific gamma globulin with soluble virion proteins, and puromycin-induced nascent protein release. The R-FeLV cDNA probe hybridized to RNA in two polyribosomal regions (approximately 400 to 450S and 250S) within the polyribosomal gradients before but not after EDTA treatment. The 400 to 450S polyribosomes contained three major peaks of virus-specific RNA at 36S, 23S, and 15 to 18S, whereas the 250S polyribosomes contained predominantly 36S and 15 to 18S RNA. Further experiments suggest that an approximately 36S minor subunit is present in virion RNA.     

The mRNA codon environment at the P and E sites of human ribosomes deduced from photo crosslinking with pUUUGUU

Three mRNA analogs--derivatives of hexaribonucleotide pUUUGUU comprising phenylalanine and valine codons with a perfluoroarylazido group attached to the C5 atom of the uridine residue at the first, second, or third position--were used for photocrosslinking with 80S ribosomes from human placenta. The mRNA analogs were positioned on the ribosome with tRNA recognizing these codons: UUU was at the P site if tRNA(Phe) was used, while tRNA(Val) was used to put there the GUU codon (UUU at the E site). Thus, the crosslinking group of mRNA analog might occupy positions -3 to +3 with respect to the first nucleotide of the codon at the P site. Irradiation of the complexes with soft UV light (lambda > 280 nm) resulted in the crosslinking of pUUUGUU derivatives with 18S RNA and proteins in the ribosome small subunit. The crosslinking with rRNA was observed only in the presence of tRNA. The photoactivatable group in positions -1 to +3 binds to G1207, while that in positions -2 or -3 binds to G961 of 18S RNA. In all cases, we observed crosslinking with S2 and S3 proteins irrespective of the presence of tRNA in the complex. Crosslinking with S23 and S26 proteins was observed mainly in the presence of tRNA when modified nucleotide occupied the +1 position (for both proteins) or the -3 position (for S26 protein). The crosslinking with S5/S7 proteins was substantial when modified nucleotide was in the -3 position, this crosslinking was not observed in the absence of tRNA.     

Structure-function correlations (and discrepancies) in the 16S ribosomal RNA from Escherichia coli.

The published model for the three-dimensional arrangement of E coli 16S RNA is re-examined in the light of new experimental information, in particular cross-linking data with functional ligands and cross-links between the 16S and 23S RNA molecules. A growing body of evidence suggests that helix 18 (residues 500-545), helix 34 (residues 1046-1067/1189-1211) and helix 44 (residues 1409-1491) are incorrectly located in the model. It now appears that the functional sites in helices 18 and 34 may be close to the decoding site of the 30S subunit, rather than being on the opposite side of the 'head' of the subunit, as hitherto supposed. Helix 44 is now clearly located at the interface between the 30S and 50S subunits. Furthermore, almost all of the modified bases in both 16S and 23S RNA appear to form a tight cluster near to the upper end of this helix, surrounding the decoding site.     

Structure of protein-deficient 50 S ribosomal subunits. Particles without 5 S RNA-protein complex retain the L7/L12 stalk and associate with 30 S subunits

50 S ribosomal subunit derivatives without the 5 S RNA-protein complex obtained either by splitting with EDTA or by reconstitution from the 23 S RNA and proteins have been studied by electron microscopy. Removal of the 5 S RNA-protein complex is shown to affect neither the overall morphology of the larger ribosomal subunit nor the mode of its association with the small subunit.